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There are two types of rife machine: AC and DC. The following is an excerpt from the book Lyme Disease and Rife Machines, by Bryan Rosner, examining the effects of DC pulsed electromagnetic fields. In addition to a DC machine’s ability to directly kill Lyme Disease spirochetes, DC machines have been shown in clinical trials to be helpful in treating other health conditions often associated with Lyme Disease. Thus DC machines are a very beneficial tool for Lyme Disease sufferers because they kill the infection while simultaneously ameliorating many debilitating, quality-of-life problems Lyme Disease sufferers face. Some of the health conditions which occur in Lyme Disease, and upon which DC PEMF (pulsed electro-magnetic fields) has proven positive effects, include:
I.
Preventing damage related to blood-flow
problems caused by stroke
.[5]
II.
Decreasing varicosity, which causes blood-flow
problems.[6]
III.
Improving symptoms of
headaches
associated with
cerebral arteriosclerosis, sequels to cerebral concussion,
depressive neurosis, or tension headache
.[7]
IV.
Decrease of arterial pressure, normalization
of blood glucose level, arrest of DIC syndrome development
in people with cerebrovascular disorders.
PEMF clearly improved the symptoms involved in
cerebrovascular disorders.[8]
V.
Improving
circulation in the brain.[9],[10],[11] In
labile hypertension, PEMF produces a hypotensive effect,
improves myocardial contractility, and increases myocardial
and coronary reserves due to reduced peripheral resistance
and stimulation of myocardial propulsion. Therapeutic
response to the treatment is attributed to
normalized function of deep brain structures.[14]
Additionally, in a study where 147 subjects underwent
magneto-therapy with the unit Magniter-AMT-01, it was found
that their hypertension conditions were significantly
improved.[15]
PEMF
increases the rate of fibrinolysis, resulting in a decrease
in fibrinogen concentration in the blood, an increase in the
level of fibrinogen degradation products, and a considerably
shorter time of fibrinolysis in plasma compared to controls
(subjects receiving a placebo).[18]
Additionally, PEMF actually prevents
hypercoagulation
.[19]
Prescription
drugs also give the body another synthetic chemical to deal
with and to detoxify in addition to Lyme neurotoxins
. One
of the most noteworthy properties of PEMF is its
regenerative effect on the joints
, connective tissue, and cartilage.
There are many scientifically documented articles,
books, and studies that show PEMF to be beneficial in almost
any type of joint
or connective
tissue problem. PEMF
helps:
I.
Cartilage regeneration and growth stimulation.[21],[22],[23],[24],[25],[26],[27],[28]
PEMF is capable of returning an older patient’s
cartilage regeneration speed to that of a younger patient.[29]
II.
Soft-tissue repair
. [30]
III.
Enhancement of collagen production in
connective tissue.[31]
IV.
Beneficial to arthritis
of all kinds.[32],[33],[34],[35],[36],[37],[38],[39],[40],[41],[42],[43] Although most studies focus specifically on PEMF, one study actually correlates direct DC current with stimulation of growth and tissue repair
as well as stimulation of
bone regeneration
. In The
effects of electric currents on ATP generation, protein
synthesis, and membrane transport in rat skin, pages
264-270, the authors explain that inducing an electrical
current of at least 50µ in living tissue inside the body
results in “stimulation of growth and tissue repair” and
“improvement of bone tissue regeneration, or osteogenesis.”
The authors go on to say that DNA metabolism is not
affected by electrical stimulation, which suggests that DNA
is unaffected by this type of electrical application.
The DC powered machine supplies both PEMF as well as
direct DC current.
Here
again the strategy of conventional doctors, often even
LLMDs, is to prescribe chemical drugs that “alleviate”
depression
by changing
brain chemistry. Selective
seratonin re-uptake inhibitors (SSRIs)
are usually the
drug of choice. These
drugs have many unwanted side effects including the
incidence of unpleasant mental symptoms such as anxiety
, insomnia
, hyperactivity
, and more. These
side effects are particularly undesirable for a Lyme Disease
sufferer because they already occur as part of the disease
process itself! And
let us not forget that the FDA just issued the king of all
paradoxical warnings for ALL anti-depressant drugs:
The “black box
” warning that states antidepressant drugs cause
suicidal thoughts and ideation. Another
reason to avoid antidepressant drugs is that it is very
important for Lyme Disease sufferers to be able to
accurately assess their symptoms at any given time.
Self-symptom assessment
is one of the
most effective tools in determining which therapies work,
which don’t, and what it feels
like to get better or worse.
A
Lyme Disease sufferer already has enough brain imbalances
caused by the infection; taking a drug to induce more
unnatural brain changes is obviously not a smart idea.
Feeding brain chemistry-altering drugs to someone
whose brain is already completely thrown off due to an
infection can cause a confusing, dangerous roller coaster
ride of symptoms. PEMF
is helpful in treating the symptoms of many types of
depression
and in some
cases can be a substitute for taking chemical
antidepressants. [44],[45],[46],[47],[48],[49],
[50],[51],[52],[53],[54],[55],[56],[57],[58],[59],[60],[61],[62],[63] In a February 2004 Science and Society article, Marianne Szegedy-Maszak reported that severely depressed patients who were taking pharmaceutical drugs for treatment and underwent brain evaluation with MRI machines actually ended up experiencing dramatic improvement in their depression from the MRI machine itself. A patient who had been so depressed she could barely speak became ebullient after the 45-minute brain scan. Then a second patient, who seemed incapable of even a wan smile, emerged actually telling jokes. The article concludes that in theory, since the brain itself is an electromagnetic organ, stimulation with electromagnetic energy appears to be beneficial in depression and possibly other illnesses such as Schizophrenia and Obsessive Compulsive Disorder
Regardless of the cause of MS, PEMF has been found helpful in improving
quality of life for MS patients.[70],[71],[72],[73],[74],[75]
I.
Accelerate nerve recovery.[76]
II.
Improve rate and quality of peripheral nerve
regeneration in rats.[77]
III.
Accelerate functional recovery and prevent or
minimize muscle atrophy in sciatic nerve injury if
administered closely following the injury.[78]
IV.
Accelerate the recovery of injured limbs and the
regeneration and maturation of myelinated axons; reduce
epineural, perineural and intraneural fibrosis; and increase
luminal cross-sectional area of intraneural vessels.[79]
A
study was conducted involving two groups of people with
organic lesions of the nervous system.
Dominant symptoms were paralysis and pareses.
Both groups received extensive treatment, but only one
group received treatment with magnetic and electrical
stimulation. The
group that received magnetic and electrical stimulation
recovered faster, indicated by radiographic and
electromyographic investigations.[80]
Alfred J. Koonin, M.B., Ch, B., Ph.D., FRCS, found that
chronic skin lesions healed much faster when treated with a
machine that produced a current range of 3mA down to .1mA
applied directly to skin wounds.[123]
As you can see, DC PEMF has many benefits
in addition to pathogen killing. [A]As a side note, most research indicates that all, or nearly all, nerve/brain damage associated with Lyme Disease IS reversible, and IS a result of ongoing infection. Brain/nerve damage associated with Lyme Disease is typically NOT permanent residual damage that hangs around after the infection is gone. When the infection is eradicated, the brain heals. [1] http://www.lymeinfo.net/psychbiblio.html A list of links to abstracts which describe the neuropsychiatric manifestations of Lyme Disease [2] http://www.emedicine.com/NEURO/topic521.htm#section~author_information Lyme Disease, Julie L Puotinen, PharmD, Clinical Coordinator of Pharmaceutical Services, Clinical Instructor, Department of Pharmacy, Saint Luke's Medical Center [3] http://www.mentalhealthandillness.com/tnaold.html The Neuropsychiatric Assessment of Lyme Disease, Robert Bransfield, M.D. [4] http://cassia.org/essay.htm When
to Suspect Lyme Disease, John D. Bleiweiss, M.D. [5] Grant G, Cadossi R, Steinberg G (1994) Protection against focal cerebral ischemia following exposure to a pulsed EMF. Bioelectromagnetics 15(3):205-216. Dept of Neurosurgery, Stanford Univ, California 94305. There is evidence that EM stimulation may accelerate the healing of tissue damage after ischemia. We studied the effects of low frequency PEMF exposure on cerebral injury in a rabbit model of transient focal ischemia (2 h occlusion followed by 4 h of reperfusion). PEMF exposure (280 V, 75 Hz, IGEA Stimulator) was initiated 10 min after the onset of ischemia and continued throughout reperfusion (6 exposed, 6 controls). MRI and histology were used to measure the degree of ischemic injury. Exposure to PEMF attenuated cortical ischemia edema on MRI at the most anterior coronal level by 65% (p<.001). On histology, PEMF exposure reduced ischemic neuronal damage in this same cortical area by 69% (p<.01) and by 43% (p<.05) in the striatum. Exposure to a PEMF of short duration may have implications for the treatment of acute stroke . PMID: 8074737, UI: 94354894 [6] Galimzianov FV (1990) [Electromagnetic therapy after phlebectomy - Article in Russian]. Khirurgiia (Mosk) May;5:108-110. Comparative analysis of outpatient treatment by means of pulsed complexly-modulated EMF (PCMEMF) applied after phlebectomy in 30 patients with varicosity of the lower limbs showed the expediency of this type of treatment in the postoperative period. Exposure of the operated on limb to PCMEMF raises the efficacy of the rehabilitation measures and reduces the terms of the patients' temporary incapacity. PMID: 2391917, UI: 90362765 [7] Grunner O (1985) [Cerebral use of a pulsating magnetic field in neuropsychiatry patients with long-term headache - Article in German]. EEG EMG Z Elektroenzephalogr Verwandte Geb Dec;16(4):227-230. 40 patients with headaches of various etiology were given pulsed magnetic field therapy (f=260 Hz; t=3 ms; induction B=1.9 mT; gradient=0.5 mT/cm). Each session lasted 0.5 h. Self-assessment statements and EEG changes were used to evaluate changes of headache intensity. EEG frequency analysis showed significant changes in % delta and alpha 1 activities (7.5-9.5/s) after use of the real treatment, as compared with sham treatment. Improved self-assessment, and EEG were found in headaches associated with cerebral arteriosclerosis, sequels to cerebral concussion, depressive neurosis, or tension headache . Pulsed magnetic field could be applied only where the EEG was physiological. PMID: 3935419, UI: 86081440 [8] Karlov VA, Rodshtat IV, Kalashnikov IuD, Kitaeva LV, Khokhlov IuK (1991) [Experience with using extremely high frequency radiotherapy of the millimeter wave range in cerebrovascular disorders - Article in Russian]. Sov Med 3:20-21. Vascular diseases of the brain (functional transient and ischemic apoplexy, circulatory encephalopathy) in 79 patients were treated by UHF EMF of millimetric wave range. 14 patients entered the control group. The data show a clear-cut trend to a decrease of arterial pressure, normalization of blood glucose level, arrest of DIC syndrome development. PMID: 1882282, UI: 91352655 [9] Lud GV (1986) [Effect of a constant magnetic field on blood circulation after experimental operations on arteries of the extremities - Article in Russian]. Vestn Khir Sep;137(9):87-88. PMID: 3538626, UI: 87071468 [10] Strelkova NI, Gavrilkov AT, Diuzhilova NF, Strel'tsova EN (1981) [Status of cerebral circulation in patients with hemiplegia of vascular and traumatic origin treated with decimeter therapy and an alternating magnetic field - Article in Russian]. Zh Nevropatol Psikhiatr 81(8):1162-1166. 181 patients with hemiparesis after a cerebral stroke or craniocerebral injury were treated by local exposure of the pathological focus to decimeter EM waves (DW) and alternating magnetic field (AMF). These treatment methods improved the cerebral circulation and hastened the restoration of motor functions, especially, if used in combination with sulfide baths, therapeutic physical exercises and massage. The therapeutic effectiveness of the DW- and AMF-therapy is confirmed objectively by so informative examination methods, as rheoencephalography, ultrasonic dopplerography, and thermography. PMID: 7315051, UI: 82087133 [11] Strelkova NI, Maslovskaia SG, Gavrilkov AG, Strel'tsova EN (1983) [Use of the EMF in patients after disturbance of cerebral circulation - Article in Russian]. Sov Med 5:35-38. PMID: 6612459, UI: 83302409 [12]
[Isolated
intracranial hypertension due to Lyme's disease] [13]
Intracranial
hypertension in neuroborreliosis. [14] Kniazeva TA, Otto MP, Markarov GS, Donova OM, Markarova IS (1994) [The efficacy of low-intensity exposures in hypertension - Article in Russian]. Vopr Kurortol Fizioter Lech Fiz Kult Jan;1:8-9. 100 hypertensive subjects with labile and stable disease were exposed to low-intensity low-frequency electrostatic field generated by the unit "Infita-A". In labile hypertension, the field produces a hypotensive effect, improves myocardial contractility, increases myocardial and coronary reserves due to reduced peripheral resistance and stimulation of myocardial propulsion. Therapeutic response to the treatment is attributed to normalized function of deep brain structures. PMID: 8171859, UI: 94225808 [15] Miasnikov IG (1992) [Magnetotherapy of initial manifestations of cerebrovascular disorders in hypertension - Article in Russian]. Zh Nevropatol Psikhiatr Im S S Korsakova 92(1):63-67. The paper is concerned with the data on 147 subjects who underwent magnetotherapy with the unit "Magniter-AMT-01" applied to the cervical area. The main group included 102 subjects, 45 person served as control. The purpose of the work was to base the application of MT under inpatient and home conditions with the use of the above-indicated unit. In view of this fact, a study was made of cerebral hemo- and thermodynamics with the aid of rheoencephalography and encephaloradiothermography under the action of different modes of the functioning of the unit "Magniter-AMT-01" (pulse and variable magnet induction fields 12-15 mTl and 30-35 mTl). A method of measuring magnetosensitivity of patients depending on the temperature reaction of the brain to a single MT session was elaborated. The greatest clinical effect was attained with the use of pulse magnetic field 15 mTl. Magnetotherapy with the use of the unit "Magniter-AMT-01" gave good results under inpatient and home conditions. The magnetosensitive patients had the highest effect. PMID: 1319653, UI: 92312254 [16]
http://chronicfatigue.about.com/cs/currenttreatments/a/coagulation.htm
Hypercoagulation Theory Viable Explanation
for Some CFS & FM Symptoms by
David Berg as told to Immune Support.
[17] Kniazeva TA, Otto MP, Markarov GS, Donova OM, Markarova IS (1994) [The efficacy of low-intensity exposures in hypertension - Article in Russian]. Vopr Kurortol Fizioter Lech Fiz Kult Jan;1:8-9. 100 hypertensive subjects with labile and stable disease were exposed to low-intensity low-frequency electrostatic field generated by the unit "Infita-A". In labile hypertension, the field produces a hypotensive effect, improves myocardial contractility, increases myocardial and coronary reserves due to reduced peripheral resistance and stimulation of myocardial propulsion. Therapeutic response to the treatment is attributed to normalized function of deep brain structures. PMID: 8171859, UI: 94225808 [18] Gorczynska E (1988) Fibrinolytical processes in rabbits activated by the magnetic field. J Hyg Epidemiol Microbiol Immunol 32(4):391-396. Dept of Biochemistry, Academy of Agriculture, Szczecin, Poland. Rabbits were exposed to a constant magnetic field of 0.005 T, 0.1 T and 0.3 T induction for 1 h/d for 28 d. The magnetic field increased the rate of fibrinolysis. A decrease in fibrinogen concentration, an increase in the level of fibrinogen degradation products and a considerably shorter time of fibrinolysis in plasma were all noted. The magnitude of these processes was proportional to duration of exposure to the magnetic field in action. These date confirms the similar effect seen in other mammalians (guinea pigs, rats). Thus, the application of a static magnetic field of intensity as low as 0.005 T to increase a fibrinolysis in the thrombotic therapy seems to be justified. PMID: 3221089, UI: 89124317 [19] Temur'iants NA, Mikhailov AV (1985) [Effect of weak alternating ultra-low frequency magnetic fields on the development of the hypercoagulation syndrome in immobilized rats - Article in Russian]. Biofizika Nov;30(6):1046-1049. The experimental results are given concerning the effect of variable magnetic field (VMF) with the frequency of 8 Hz and intensity 4 A/m on some parameters of rat haemocoagulation system under standard mobile regime as well as under prolonged hypokinesia. It is stated that repeated daily exposition of VMF causes hypocoagulational blood shift in intact animals. Under the effect of simultaneous VMF and hypokinesia the correction of hypercoagulational shift induced by animal hypokinesia was found. The highest VMF effect was seen in prolonged experiments. The ability of VMF with the given parameters to limit the development of rat blood hypercoagulation under hypokinesia was discussed. PMID: 4074760, UI: 86077826 [20] Journal of the American Academy of Orthopaedic Surgeons , May-June 2004;12(3):139-43 [21] Aaron RK, Ciombor DM (1993). Increase in proteoglycan synthesis in cartilage explant cultures exposed to pulsed fields. Proceedings of the Thirteenth Annual Meeting of the Bioelectrical Repair and Growth Society; October 10-13, 1993; Dana Point, CA. BRAGS, 2. [22] Aaron RK, Ciombor DM (1992). Stimulation with pulsing electromagnetic fields act synergistically with growth factors to increase cartilage matrix synthesis. Proceedings of The First World Congress for Electricity and Magnetism in Biology and Medicine, June 14-19, 1992. Lake Buena Vista, FL, (N-1)41-42. [23]
Aaron RK, Ciombor DM (1992). Synergistic effects of growth
factors and pulsed fields on proteoglycan synthesis in
articular cartilage. Proceedings of the 38th Annual
Meeting. Orthopaedic Research Society, Feb 17-20, 1992.
Washington, DC, 17(2):527. [24] Aaron RK, Plass AHK (1987). Stimulation of proteoglycan synthesis in articular chondorcyte cultures by a pulsed electromagnetic field. Trans Orthop Res Soc, 12:273. [25] Aaron RK, Ciombor DM, Jolly G (1987). Modulation of chondrogenesis and chondrocyte differentiation by pulsed electromagnetic fields. Trans Orthop Res Soc, 12:272. [26] Brighton CT, Unger AS, Stambough JL (1984). In vitro growth of bovine articular cartilage chondrocytes in various capacitively coupled electrical fields. J Orthop Res, 2(1):15-22. [27] Canaday DJ, Lee RC (1991). Scientific basis for clinical applications of electric fields in soft-tissue repair. In Brighton CT, Pollack SR, eds. Electromagnetics in Biology and Medicine. San Francisco, CA: San Francisco Press, Inc., chap 44. [28] Ciombor DM, Aaron RK(1993). Pulsed fields act synergistically with growth factors to increase cartilage matrix synthesis. Proceedings of the Thirteenth Annual Meeting of the Bioelectrical Repair and Growth Society; October 10-13, 1993; Dana Point, CA. BRAGS, 3. [29] Ciombor DM, Aaron RK(1993). Pulsed fields act synergistically with growth factors to increase cartilage matrix synthesis. Proceedings of the Thirteenth Annual Meeting of the Bioelectrical Repair and Growth Society; October 10-13, 1993; Dana Point, CA. BRAGS, 3. [30] Canaday DJ, Lee RC (1991). Scientific basis for clinical applications of electric fields in soft-tissue repair. In Brighton CT, Pollack SR, eds. Electromagnetics in Biology and Medicine. San Francisco, CA: San Francisco Press, Inc., chap 44. [31] Farndale RW, Murray JC (1985). Low frequency pulsed magnetic fields enhance collagen production in connective tissue. Bioelectrochem Bioenerg, 14:83-91. [32]A
study of the effects of pulsed electromagnetic field
therapy with respect to serological grouping in rheumatoid
arthritis
. [33]
A
case of congenital pseudarthrosis of the tibia treated
with pulsing electromagnetic fields. 17-year follow-up. [34]
Comparison
between the analgesic and therapeutic effects of a
musically modulated electromagnetic field (TAMMEF) and
those of a 100 Hz electromagnetic field: blind experiment
on patients suffering from cervical spondylosis or
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Fortunato M, Giordano N. Department of Physics, Section of
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